´Obuda University PhD thesis abstract Study of complex

´
Obuda
University
PhD thesis abstract
Study of complex nanostructures by infrared spectroscopy
Zsolt Szekr´
enyes
Doctoral School on Materials Sciences and Technologies
Supervisor: Dr. Katalin Kamar´
as
Institute for Solid State Physics and Optics
Wigner Research Centre for Physics
Hungarian Academy of Sciences
Budapest, 2015
Introduction
The formation and breaking of hydrogen bonds is one of the most fundamental processes in biology, chemistry, and materials science. For example, hydrogen
bonding is responsible for the formation of the DNA double helix and for the
highly unusual phase diagram of water or the secondary and tertiary structures
in proteins; it is therefore at the very heart of life sciences. Furthermore, with
the continuous down-scaling of technology in mind, the self-assembly and molecular recognition properties of hydrogen bonds have found their way into the
fabrication of nanoscale materials and devices [1–3]. It is therefore imperative
to understand the microscopic mechanisms that lead to the formation and dissolution of hydrogen bonds, in particular their temperature dependence. The
energy of these weak interactions between the supramolecular constituents is
comparable to the thermal energy slightly above room temperature so such systems are very dynamic: weak interactions can be broken and formed back again
within very short time scales [4]. In the first part of my PhD work I studied uracil
and acetylamino-pyridine based molecules which form supramolecular assemblies
through hydrogen bonds.
The second part of my thesis presents a study on silicon carbide quantum
dots. Silicon carbide is a stable, chemically inert wide band gap semiconductor
with excellent hardness, heat resistance and chemical resistivity [5, 6]. Silicon
carbide is also known as a biocompatible material with very promising results
in living cell implantation for bioimaging techniques [7, 8]. The emergence of
nanotechnology in the field of cell biology gave rise to the implementation of
quantum dots in cell labeling. Considering the requirements for the ideal in vivo
luminescent biomarkers (to be nontoxic, bioinert, photostable, not blinking, ultra small size) and comparing to the widely used II-VI semiconductor quantum
dots (e.g. CdSe), silicon carbide quantum dots are among the best candidates
for biological applications [9]. Further applications of the silicon carbide quantum dots in medicine and drug delivery rely on the ability of engineering the
desired surface properties by attaching different functional molecular groups.
To obtain tailor-made functionalized surfaces it is necessary to understand the
complex structure of the quantum dots surface. During my work I studied the
surface structure of the silicon carbide quantum dots by surface sensitive infrared
spectroscopy and photoluminescence spectroscopy.
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Objectives
First task of my work was to prepare an infrared spectral library on the
molecules synthesized by our partners. These molecules have different functional sites which permit the self-assembly through hydrogen bonding. Starting from the basic molecular units and finishing with the final supramolecular
assemblies, I studied the supramolecular ordering of different imide-uracil and
acetylaminopiridyne based molecular constituents to understand the microscopic
mechanisms that lead to the formation and dissolution of hydrogen bonds.
Silicon carbide quantum dots are very promising material for different biological applications due to their bioinert and biocompatibility properties. They
show very interesting and promising luminescent properties as well as a complex surface structure. The main task during my work was to study the surface
structure of the quantum dots by infrared and photoluminescence spectroscopy.
Surface sensitive infrared spectroscopy revealed the presence of carboxyl and
carboxilate groups on the surface of silicon carbide quantum dots, opening the
possibility for further biological functionalization.
Methods
The main experimental method used during this work was infrared spectroscopy. In the first part of my thesis I used different methods of infrared
spectroscopy to characterize the molecules in isolated and aggregated state. Matrix isolation infrared spectroscopy was used to study the molecules in their
monomeric state when no interaction between them is possible. In the aggregated
state hydrogen bonds represent the main interaction between the molecules. To
reveal the exact dimeric or multimeric character of the hydrogen bonded structures, temperature dependent measurements were used to study the stability of
the hydrogen bonds.
The study of the surface structure of silicon carbide quantum dots requires
surface sensitive methods of infrared spectroscopy. These methods permit the
identification of atomic monolayers and surface functional molecular groups. One
of the methods used and implemented during my PhD work in our laboratory is
attenuated total internal reflection (ATR) infrared spectroscopy. Using standard
infrared spectroscopic methods I found clear evidence of chemical transformation
of carboxylic groups on the surface of silicon carbide quantum dots to acid anhy2
dride groups at elevated temperatures. Finally, photoluminescence spectroscopy
was used to reveal the luminescent properties of the quantum dots.
Theses
1. I prepared an infrared spectral library for the molecular constituents for
hydrogen bonded systems. Starting from the basic molecular units and finishing with the final supramolecular assemblies I measured and interpreted
the infrared spectra of the supramolecular ordering of different imide-uracil
and acetylaminopiridyne based molecular constituents by infrared transmission spectroscopy [T1, T2, T3].
2. I studied the direct evidence of the presence of hydrogen bonds for a pair
of monotopic uracil-derivative molecules measuring the spectra of the isolated molecules and that of the aggregated state. For this I applied different methods of infrared spectroscopy: matrix isolation and conventional
transmission spectroscopy. I could identify the weakening and subsequent
disruption of hydrogen bonds by following the temperature dependence of
the affected vibrational bands. The assignment of the processes responsible for the melting of hydrogen bonds was done: a gradual increase of
the temperature to intermediate values induces large thermal fluctuations
in the dimers that leads to a thermal equilibrium between different dimer
configurations. I found that further increase of the temperature above the
sublimation point of the molecules the hydrogen bonds are disrupted, indicating that the sublimation temperature provides a good estimate for
hydrogen bond stability in such systems. These results are consistent with
theoretical results [T2].
3. I studied the supramolecular ordering in the solid state of bis-uracil
based linear molecules by different infrared spectroscopic methods. A
temperature-induced transition from a highly ordered tetrameric into a
linear assembly was observed by temperature dependent infrared measurements. The interaction between molecules in the three perpendicular directions of the solid crystal is governed by three different noncovalent interactions: double hydrogen bonds, van der Waals attraction and π-π stacking
[T3].
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4. I performed room temperature infrared and photoluminescence measurements on silicon carbide quantum dots dispersed in different solvents (water, ethanol, and butanol). Infrared spectroscopy has revealed the complex
surface structure of quantum dots involving the presence of COOH and
COO- molecular groups which are important for further functionalization
processes [T4, T5].
5. Performing temperature dependent infrared and photoluminescence investigations I found evidence for chemical transformation of carboxylic groups
to acid anhydride groups on the surface of silicon carbide quantum dots.
Acid anhydride formation was observed above 370 K by water elimination between two neighboring carboxyl groups. Photoluminescence results
show that silicon carbide quantum dots emission properties are highly sensitive to the surface structure of quantum dots and to the surface-solvent
interactions [T6].
Conclusions and Outlook
After studying prototypical molecules able to form hydrogen bonded
supramolecular systems and presenting basic spectroscopic properties of silicon
carbide quantum dots one major question arises: how ’potential’ are the potential applications? Even if many supramolecular approaches were suggested for
the preparation of self-assembled systems, to the best of my knowledge, no final
devices for real life applications have been created yet. However, the increasing knowledge in controlling the location and accessibility of the molecules in
a supramolecular network demonstrates that the ”bottom-up” approach is getting closer and closer to industrial applications. Challenging requirements are
set up also for quantum dots. For applications in bioimaging and biolabelling
techniques a quantum dot must fulfill, at the same time, the following criteria:
it should be nontoxic, bioinert, photostable, should be no blinking, be small, be
producible in large amounts and show luminescent emission in a range specific
to the desired application. Even if no ideal quantum dot was found yet, there are
several potential candidates like core-shell quantum dots prepared from group
II-VI elements, nanodiamond, carbon dot, and of course silicon carbide. Which
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of these will be finally used in real world applications? Hopefully the right answer
is silicon carbide.
Publications related to the thesis points
[T1] L. Piot, C. A. Palma, A. Llanes-Pallas, Zs. Szekr´enyes, K. Kamar´as, M.
Prato,D. Bonifazi and P. Samor`ı, Selective formation of bi-component
arrays through H-bonding of multivalent molecular modules, Adv. Funct.
Mater., 19:1207, 2009 (cover page).
[T2] Zs. Szekr´enyes, K. Kamar´
as, G. Tarczay, A. Llannes-Pallas, T. Marangoni,
M. Prato, D. Bonifazi, J. Bjork, F. Hanke, M. Persson, Melting of Hydrogen Bonds in Uracil Derivatives Probed by Infrared Spectroscopy and ab
Initio Molecular Dynamics, J. Phys. Chem. B, 116:4626, 2012.
[T3] Zs. Szekr´enyes, K. Kamar´
as, P. Nagy, G. Tarczay, A. Llannas-Pallas, L.
Maggini, M. Prato, D. Bonifazi, Direction-dependent secondary bonds
and their stepwise melting in a uracil-based molecular crystal studied by
infrared spectroscopy and theoretical modeling, under submission.
´ Fazakas, L. K. Varga,
[T4] D. Beke, Zs. Szekr´enyes, I. Balogh, M. Veres, E.
K. Kamar´
as, Zs. Czig´
any, and A. Gali, Characterization of luminescent
silicon carbide nanocrystals prepared by reactive bonding and subsequent
wet chemical etching, App. Phys. Lett. 99:213108, 2011.
[T5] D. Beke, Zs. Szekr´enyes, I. Balogh, Zs. Czig´any, K. Kamar´as, A. Gali,
Preparation of small silicon carbide quantum dots by wet chemical etching, J. Mater. Res., 28:44, 2013.
[T6] Zs. Szekr´enyes, B. Somogyi, D. Beke, Gy. K´arolyh´azy, I. Balogh, K. Kamar´
as, and A Gali, Chemical transformation of carboxyl groups on the
surface of silicon carbide quantum dots, J. Phys. Chem. C, 118:19995,
2014.
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Further publications
[F1] E. Horv´
ath, M. Spina, Zs. Szekr´enyes, K. Kamar´as, R. Gaal, D. Gachet, L.
Forr´
o, Nanowires of lead-methylamine iodide (CH3 NH3 PbI3 ) prepared by
low temperature solution-mediated crystallization, Nano Lett., 14:6761,
2014.
´ Pekker, B. A.
´ Pataki, Zs. Szekr´enyes, K. Kamar´as: Bun[F2] H. M. T´
oh´
ati, A.
dle vs. network conductivity of carbon nanotubes separated by type, Eur.
Phys. J. B, 87:126, 2014.
[F3] B. Botka, M. E. F¨
ust¨
os, H. M. T´
oh´
ati, K. N´emeth, Gy. Klupp, Zs.
Szekr´enyes, D. Kocsis, M. Utcz´
as, E. Sz´ekely, T. V´aczi, Gy. Tarczay, R.
Hackl, T. W. Chamberlain, A. N. Khlobystov, K. Kamar´as: Interactions
and Chemical Transformations of Coronene Inside and Outside Carbon
Nanotubes, Small, 10:1369, 2014.
[F4] C. Frigeri, M. Ser´enyi, A. Csik, Zs. Szekr´enyes, K. Kamar´as, L. Nasi, N.Q.
Kh´
anh, Evolution of the structure and hydrogen bonding configuration in
annealed hydrogenated a-Si/a-Ge multilayers and layers, App. Surf. Sci.,
269:12, 2013.
[F5] M. Ser´enyi, C. Frigeri, Zs. Szekr´enyes, K. Kamar´as, L. Nasi, A. Csik, N.
Q. Kh´
anh, On the formation of blisters in annealed hydrogenated a-Si
layers, Nanoscale Res. Lett., 8:84, 2013.
[F6] D. Beke, Zs. Szekr´enyes, D. P´
alfi, G. R´
ona, I. Balogh, P. A. Ma´ak, G.
Katona, Zs. Czig´
any, K. Kamar´
as, B. R´
ozsa, L. Buday, B. V´ertessy and
A. Gali, Silicon carbide quantum dots for bioimaging, J. Mater. Res.,
28:205, 2013.
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